Dispersible anthraquinone dyestuffs

ABSTRACT

1-V1,2-(R&#34;-O-CO-O-Y&#39;&#39;-X2-),4-V2&#39;&#39;-ANTHRAQUINONE   DIFFICULTLY WATER-SOLUBLE ANTHRAQUINONE DYESTUFFS FREE FROM WATER-SOLUBILIZATING GROUPS WHICH DISSOCIATE ACID IN WATER OF THE FORMULA WHEREIN V1 REPRESENTS HYDROXYL OR --NH2, V2&#39;&#39; REPRESENTS HYDROGEN, HYDROXYL, PHENYLAMINO OR PHENYLAMINO RING-SUBSTITUTED BY ONE SUBSTITUTED SELECTED FROM CHLORINE AND C1-C4 ALKOXY OR BY ONE TO THREE C1-C4ALKYL, X2 REPRESENTS OXYGEN,SULPHUR, --CO--O--, --CONH--, --SO2--O--, --SO2NH-- OR --O--ALKYLENE--O--, WHEREIN THE ALKYLENE MOIETY HAS AT MOST 4 CARBON ATOMS, Y&#39;&#39; IS AN ALIPHATIC, AROMATICOR HETEROCYCLIC BRIDGE, AND R&#34; IS ALKYL, CYCLOHEXYL OR ARYL; THESE DYESTUFFS BEING SUITED PARTICULARLY FOR THE DYEING OF SYNTHERIC ORGANIC FIBERS, ESPECIALLYPOLYETHYLENE GLYCOL TEREPTHALATE FIBERS, AFFORDING DYEINGS ON THESE FIBERS WHICH HAVE GOOD FASTENESS PROPERTIES AND ESPECIALLY FOOD FASTENESS TO LIGHT AND SUBLIMATION.

United States Patent Int. C1. (509:, 1/54, 1/56 UeS. Cl. 260-376 6 Claims ABSTRACT OF THE DISCLOSURE Difficultly water-soluble anthraquinone dyestufis free from water-solubilizing groups which dissociate acid in water of the formula 0 V1 ll i is wherein V represents hydroxyl or -NH V represents hydrogen, hydroxyl, phenylamino or phenyl amino ring-substituted by one substitueut selected from chlorine and C -C alkoxy or by one to three C -C alkyl,

X, represents oxygen, sulphur, COO-, CONH, S0gO-, SO NH- or Oalkylene-O, wherein the alkylene moiety has at most 4 carbon atoms,

Y" is an aliphatic, aromatic or heterocyclic bridge, and

R" is alkyl, cyclohexyl or aryl;

these dyestuffs being suited particularly for the dyeing of synthetic organic fibers, especially polyethylene glycol terephthalate fibers, alfording dyeings on these fibers which have good fastness properties and especially good fastness to light and sublimation.

This application is a continuation-in-part of application Ser. No. 24,810, filed Apr. 1, 1970, now US. Pat. No. 3,689,510.

The present invention relates to sparingly water-soluble anthraquinone dyestufis, usable as dispersion dyestuffs, to processes for their production, to the use of these anthraquinone dyestuffs for the dyeing or printing of synthetic organic textile fibres, especially textile fibres made from linear polyesters of aromatic polycarboxylic acid with polyfunctional alcohols, or made from cellulose esters and, the textile fibres dyed or printed with said dyestufis.

It has been found that difficultly water-soluble anthraquinone dyestuffs being free from water-solubilizing groups dissociating acid in water and corresponding to the Formula I,

are characterized by particularly advantageous properties e.g. good affinity on polyester fibres combined with good fastness to light and sublimation of the dyeings produced therewith.

In the above Formula I A represents the radical of an anthraquinone dyestuff which is linked with Y, in at least one ,fi-position, either directly or by way of a bridging member,

Y represents an alkylene group, optionally substituted by a hydroxyl group, and

Patented Apr. 23, 1974- R represents an optionally substituted aliphatic, cycloaliphthatic or aromatic radical.

The anthraquinone dyestuffs of Formula I are obtained by condensing an anthraquinone compound of the Formula II,

A-YOH (II) wherein Hal represents chlorine or bromine and R has the meaning given under Formula I. a

The starting materials areso chosen that the obtained anthraquinone .dyestutf contains no water-solubilizing groups dissociating acid in water, i.e. it contains, e.g. no sulphonic acid groups, carboxylic acid groups or ph0S-' phoric acid groups.

The anthraquinone compounds, usable as starting materials and containing, in at least one fl-position, a hydroxyalkyl radical bound either directly or by way of a bridging member to the anthraquinone nucleus, can be long to the series of the actual anthraquinonyl compounds as well as to that of the higher condensed derivatives, i.e. to the group of the anthraquinonyl or anthrapyrimidinyl compounds.

The anthraquinone nucleus can contain, in addition to the substituents YO-OOOR in B-position, further substituents, e.g. primary amino groups or secondary amino groups which can be substituted by a lower alkyl group such as the methyl, isopropyl or see. butyl group, a cycloalkyl group such as the cyclohexyl group, a monoor polynuclear aryl group, e.g. phenyl, chlorophenyl, methylphenyl such as the toluyl or 2,4,6-trimethylphenyl group, methoxyphenyl, phenoxyphenyl or phenylazophenyl group as well as hydroxy, cyano or nitro groups, or halogen such as fluorine, chlorine or bromine.

The anthraquinone radical A can be bound direct to Y or by way of bivalent or trivalent bridging member. Bivalent bridging members can be double-bonding atoms such as oxygen or sulphur, or double-bonding groups. Suitable double-bonding groups are, e.g. those containing heteroatoms, e.g. a

group (whereby R denotes hydrogen or a lower alkyl radical, the alkylene group has at most 4 carbon atoms and the phenylene group may be substituted by halogen such as chlorine, or lower alkyl groups). Suitable as trivalent bridging member is, in particular, the o-dicarboxylic acid imide group. The alkylene group Y contains preferably at most 4 carbon atoms and can be straight-chained or branched; in the former case it is preferably the 1,2-ethylene or 1,3- propylene group, in the latter case it is the 2-methyl-l,3 propylene or 2,2-dimethyl-l,3-propylene group. If the alkylene group Y is substituted by a hydroxyl group, it represents especially a 2-hydroxy--l,3-propylene group.

If R represents an aliphatic radical, then it is, e.g. a straight or branch-chained, optionally substituted alkyl or alkenyl group (in the latter case especially a A -alkenyl group) having preferably up to 5 carbon atoms. As substituents, these aliphatic radicals, especially the alkyl group, can contain, e.g. halogen such as chlorine or bromine, or a lower alkoxy group as well as a carbocyclic ring having, in particular, aromatic character such as the phenyl radical, or heterocyclic n'ngs such as the thinenyl- (2)-, furyl-(2)- or tetrahydrofuryl-(2)-radical.

Cycloaliphatic radicals denoted by R are, e.g. cycloalkyl groups having preferably or 6-membered rings and especially the cyclohexyl or methylcyclohexyl group.

When R represents an aromatic radical, then this radical preferably belongs to the benzene series; it can contain usual non-ionogenic ring substituents. Such substituents are, e.g. halogenes such as fluorine, chlorine or bromine, or lower alkyl groups, preferably chlorine or methyl groups.

Starting materials of the Formula H are for the most ,part known or they can be produced by methods known per se.

- Anthraquinone compounds of the Formula II, in which the radical A is bound to Y by way of oxygen, sulphur, an

group, can be obtained, e.g. using the process of the German Pat. 1,209,680 or of the British Pat. 974,404, e.g. by reacting an anthraquinone compound of the Formula IV,

A'W (IV) wherein A represents a B-anthraquinonyl radical, and W represents halogen, the sulphonic acid group or a phenoxy group,

with a compound of the Formula V,

wherein Y has the meanings given under Formula I, and

X represents oxygen or sulphur, and

Q represents the direct bond or a bivalent hydrocarbon radical optionally interrupted by oxgen.

Examples of anthraquinone compounds of the Formula IV are:

l-amino-Z-bromoanthraquinone, l ,4-diamino-2-bromoanthraquinone, 1-amino-4-hydroxy-2-bromoor -2-chloroanthraquinone, l-amino-4-hydroxy-2-phenoxy-anthraquinone, l-amino-4hydroxyanthraquinone-Z-sulphonic acid, 1-amino-4-phenylaminoanthraquinone-Z-sulphonic acid, 1-amino-4-cyclohexylaminoanthraquinone-Z-sulphonic acid 1-amino-4-hydroxy-2-p-methoxyphenoxy-anthraquinone.

Examples of compounds of the Formula V are: glycols such as ethyleneglycol, 1,3-propyleneglycol, 2,2-diethylpropanediol-(1,3, cyclohexanedimethanol, cyclohexanediethanol, cyclohexanedi n butanol, 2,5-bis-(hydroxymethyl) tetrahydrofuran, 2,5 bis (B-hydroxyethyhtetrahydrofuran, di-(B-hydroxyethoxy)-benzene, also mor p ()3 hydroxyethoxy)-phenol, fl-(p-hydroxy-phenylethyl alcohol, m-hydroxybenzyl alcohol, mercaptoalkyl alcohols such as 2-mercaptoethanol, 3-mercapto-1- propanol or 4-mercapto-l-butanol.

Starting materials of the Formula II, in which Y is bound to A by way of a 4O NH or -CONH-- group or by way of a OphenyleneSO NH, -OphenyleneCONH--, SphenyleneSO NH- or Sphenylene--CONH group, can be obtained by reacting a halide of the Formula VI,

wherein A represents a fl-anthraquinonyl radical,

Q represents the direct bond or a phenylene group which is linked to A by way of oxygen or sulphur,

X represents the CO-- or SO bond, and

Hal represents chlorine or bromine,

with an amine of the Formula VII,

NH YOH whereinY has the meaning given under Formula 1.

(VII) Halides of the Formula VI are, e.g.

l-aminoanthraquinone-Z-carbonyl chloride,

l-amino-4-phenylaminoanthraquinone-Z-carbonyl chloride,

l-amino-4-hydroxy-anthraquinone-2-phenoxy-3'- carbonyl chloride,

l-amino-4-hydroxy-anthraquinone-2-phenoxy-4'- sulfonylchloridc, or

1-amino-4-hydroxy-anthraquinone-2-phenylthio-4'- sulfonyl chloride,

1,4-diamino-2-hydroxymethyl-anthraquinone, 1,4-dihydroxy-Z-hydroxymethyl-anthraquinone, 1-amino-2-hydroxymethyl-4-phenylamino-anthraquinone,

and 1-hydroxy-2-hydroxymethyl-4-phenylamino-anthraquinone.

The halogeno formic acid esters of the Formula III,

usable as starting materials, are likewise for the most part known.

Such esters are: halogeno formic acid-alkyl, -alkenyl,'

-cycloalkyl or -aryl esters, e.g. chloroformic acid methyl ester, chloroformic acid ethyl ester, chloroformic. acid' isopropyl ester, chloroformic acid amyl ester, chloroformic acid allyl ester, chloroformic acid cyclohexyl ester, chloroformic acid-' -chloropropyl ester, chloroformic acid phenyl ester or chloroformic acid-2,4-dimethylphenyl ester, chloroformic acid-4-chlorophenyl ester, as well as the corresponding bromine derivatives.

The reaction of the anthraquinone compounds of the Formula II with the halogeno formic acid esters of Formula III is preferably performed at low temperatures (0-50 C.) in the presence of acid-binding agents and, optionally, in inert organic solvents.

Suitable acid-binding agents are, in particular, tertiary nitrogen bases such as pyridine, picoline, quinoline, lepidine, aliphatic amines such as trimethylamine and triethylamine, anilines such as N,N-dimethylaniline and N,N-diethylaniline, also alkali metal or alkaline-earth metal carbonate, hydrogen carbonates or hydroxides such as sodium hydrogen carbonate, potassium carbonate, barium carbonate, sodium hydroxide or barium hydroxide. Suitable inert organic solvents are optionally halogenated or nitrated aromatic hydrocarbons such as toluene, xylene, chlorobenzene, dichlorobenzene or nitrobenzene as well as aliphatic halogenated hydrocarbons such as chloroform, carbon tetrachloride or tetrachloroethane, also lower aliphatic ketones such as acetone and cyclic ethers such as dioxane or tetrahydrofuran.

Preferred anthraquinone dyestuffs of the Formula I, which are characterized by a good affinity, by good levelling and build-up properties as well as by good fastness to sublimation and light on polyethylene glycol terephthalate fibres, correspond to the Formula VIII,

V; II I V; (VIII) wherein V, represents the hydroxyl or amino group,

V represents the hydroxyl group or a phenylamino group, optionally ring-substituted by halogen such as chlorine, lower alkyl or lower alkoxy group,

X; represents oxygen, sulphur, the CONH- or group, or also an -Oalkylene0- group,

Y represents a lower alkylene group, and

R" represents a lower alkyl group or a phenyl radical, optionally substituted by halogen, such as chlorine, or a lower alkyl group such as a methyl group.

Further anthraquinone dyestuffs, according to the invention, which likewise are characterized by a good affinity and levelling property, as well as by good fastness to light of the polyester dyeings produced therewith, are those of the Formulae IX and X,

C HgO-C O O R" [I I O V: and

NH h) OH (0-Y')i:-0C O O R H NH-R' wherein V V Y' and R" have the meaning given under Formula VIII, and R represents a lower alkyl group or preferably hydrogen.

In this specification, including the claims, the term lower applied to alkyl, alkylene and alkoxy" groups or moieties means that such groups or moieties have at most 5 carbon atoms.

Anthraquinone dyestuffs of Formula I, wherein the RO0C-OY grouping is linked to the anthraquinone nucleus by way of a NHphenylene,

NHphenylene-O or NH-phenyleneS- group may also be produced by condensing a fihalogenoanthraquinone compound of Formula XI,

A"Hal (XI) wherein A represents a ,B-anthraquinonyl radical which contains a hydroxyl group in the adjacent a-position, and Hal represents chlorine or bromine,

with an amino compound of Formula XII,

NH -arylene--Q"YO-COOR (XII) wherein arylene represents a benzene nucleus, optionally substituted by halogen such as chlorine, or by lower alkyl groups,

Q represents the direct bond, oxygen or sulphur, and Y and R have the meaning given under Formula I,

whereby the starting materials are so chosen that the final dyestuff contains no water-solubilizin-g groups dissociating acid in water.

fi-Halogeno-anthraquinone compounds of Formula XI, usable according to the invention, are for the most part known. Examples of these are: l-hydroxy-Z-bromoanthraquinone, l,4-dihydroxy 2 bromo-anthraquinone and 1,4dihydroxy-Z-chloro-anthraquinone.

Amines of the Formula XII to be reacted with the latter compounds of the Formula XI can be produced in a known manner e.g. by reacting a. nitro compound of the Formula XIII,

wherein arylene, Q" and Y have the meaning given above, with a halogeno formic acid ester of the Formula III given above, whereby the condensation is performed as described in the foregoing, and then reducing the nitro group to the amino group.

Furthermore, anthraquinone dyestuffs falling under Formula I and corresponding to the Formula XIV,

ball

I NH-R' (XIV) wherein R represents hydrogen or a lower alkyl group, n represents 1 or 2, and

R and Y have the meaning given under Formula I, and

wherein the benzene ring B may be further substituted by halogen or lower alkyl groups, may be produced by con densing a disulfonated anthraquinone compound of Formula XV to a monosulfonated anthraquinone compound of Formula XVII HO O NH-R' (XVII) and then splitting off the sulphonic acid group of this latter compound with a reducing agent, whereby the starting materials are so chosen that the final dyestutf contains no water-solubilizing groups dissociating acid in water.

A further process for the production of anthraquinone dyestuffs of the Formula XIV comprises oxidizing an anthraquinone compound of Formula XVIII,

HO ii I IHR' (XVIII) wherein R represents hydrogen or a lower alkyl group, to the corresponding quinonimino compound, for example with manganese dioxide and then reacting the latter with a compound of the Formula XVI given above, whereby the starting materials are so chosen that the final dyestuff contains no water-solubilizing groups dissociating acid in water.

The new anthraquinone dyestuffs of the Formula I are yellow to deeply colored, crystalline, difficultly watersoluble substances. They can be obtained analytically pure by recrystallization from organic solvents, but such purification is generally not necessary for their use in dyeing.

They are suitable for the dyeing or printing of synthetic organic fibres, e.g. for the dyeing of textile fibres made from linear, high-molecular esters of aromatic polycarboxylic acids with polyfunctional alcohols such as polyethylene glycol terephthalate or poly-(1,4-cyclohexanedimethylol-terephthalate) as well as for the dyeing of textile fibres made from cellulose-2-, -2l-acetate or cellulose triacetate. These dyestuffs can, however, also be used for the dyeing of synthetic polyamide fibres such as polyhexamethylene adipamide, polycaprolactam or polyaminoundecanoic acid, as well as for the dyeing of polyolefins, especially polypropylene fibres, and also for the dyeing of polyamide in the mass.

Furthermore, they are suitable, depending on the composition, for the dyeing of lacquers, oils and waxes, as well as for the dyeing of cellulose derivatives, particularly cellulose esters such as cellulose acetate, in the mass.

Preferably, the dyeing of the mentioned fibre materials with the difiicultly water-soluble anthraquinone dyestufl's, according to the invention, is carried out from aqueous dispersion. It is therefore advantageous to finely dividethe final materials of the Formula I, usable as dispersion dyestuffs, by grinding them with dispersion agents and possibly with further grinding auxiliaries.

Anionic dispersing agents suitable for the purpose are, e.g. the alkylaryl sulphonates, the condensation products of formaldehyde with naphthalene sulphonic acid, the lignin sulphonates; suitable non-ionogenic dispersing agents are, e.g. the fatty alcohol or alkylphenyl-polyglycol ethers with higher alkyl radical.

The dyeing of the polyester fibres with the difiicultly water-soluble dyestuffs, according to the invention, from aqueous dispersions, is carried out by the usual processes for polyester materials. Polyesters of aromatic polycarboxylic acids with polyvalent alcohols are preferably dyed at temperatures of above 100 C. under pressure. But the dyeing can also be performed at the boiling point of the dye bath in the presence of dye carriers, e.g. phenylphenols, polychlorobenzene compounds or similar auxiliaries, or by using the Theromosol process, i.e. paddyeing with a subsequent treatment in the heat, e.g. thermofixing at 180-210 C. Cellulose-2 /-acetate fibres are preferably dyed at temperatures of 80-85 C., whereas cellulose triacetate fibres, as well as synthetic polyamide fibre material, are advantageously dyed at the boiling point of the dye bath. The use of dye carriers is not necessary in the dyeing of cellulose-2 /z-acetate or polyamide fibres. Anthraquinone dyestuffs, according to the invention, can also be used for the printing of the stated materials using normal methods.

The anthraquinone dyestuffs of the Formula I, usable as dispersion dyestuffs, draw on to the previously mentioned synthetic organic fibre material, especially on to polyethylene glycol terephthalate textile fibres, very well and they produce thereon strong yellow, orange, red, violet, blue and green dyeings which have very good fastness to light, washing, rubbing, perspiration, sublimation, solvents and decatizing. In this respect, mixtures of anthraquinone dyestuffs according to the invention behave particularly favorably.

Furthermore, anthraquinone dyestuffs, according to the invention, can also very well be used in admixture with other dispersion dyestuffs, which are fast to sublimation, for the dyeing of textile material using the paddyeing/thermofixing process. Particularly worthy of note is the fact that dyestuffs of the Formula I produce, in the dyeing of closely woven polyester fabrics or firmly twisted polyester yarns, even dyeings right through.

Moreover, the dyestuffs of the FormulaI possess the valuable property of being able to produce on textured polyester fibres, e.g. Crimplene, very deep and nonstreaky dyeings which also have good fastness properties, particularly fastness to light and sublimation. The new anthraquinone dyestuffs also have good stability in the dye liquor and to boiling.

The following examples illustrate the invention. The temperatures are given in degrees centigrade.

EXAMPLE 1 ocmcmocoo-Q precipitates, on stirring the solution with 300 g. of methanol at 20, in a crystalline form; it is filtered off, washed with methanol and dried.

Fibres made from cellulose diand triacetate, as well as from polyethylene terephthalate, are dyed in the aqueous dispersion of this finely divided dyestuff in very pure and even red shades. The dyeings have very good fastness to light, sublimation and rubbing.

If, instead of the 29.9 g. of 1-amino-2-;3-hydroxyethoxy- 4-hydroxyanthraquinone, equivalent amounts of an anthraquinone compound listed in the following Table 1, column II, are used, and instead of the 31 g. of chloroformic acid phenyl ester, equivalent amounts of a halogen formic acid ester given in column III of the same table, using otherwise the same procedure as described in the example, then dyestuffs are obtained which dye polyethylene glycol terephthalate fibres in the shades listed in column IV of this table, these shades likewise having fastness to light and to sublimation.

TABLE 1 Shade on polyethylene glycol terephthalato Number Anthmqulnoue compound Halogen formic acid ester fibres 2 O NH; Red.

II 1 CH: ClCOO CH: A ocml sm-cmoa &

3..." (EH f) OH ClCOOCHgCCh Orange.

0 CHaCHaOH 4 i) NH; ClCOOCHzCl Red.

/\ OCHQ-CHIOH 5.. (I) NH: ClCOOCH| Red.

A o cmcmon Y em 6 O NH| m ClCO0CHz-CH=CH1 Red.

n I i E OCHrL CHaOH 7 O NH: Red.

I OH; CIC 0 O CH:

-OCH|A!-CH2OH 8 O OH Orange.

Cl-C OO- CH| S CHaCHaOH ll 0 H 9 0 NH! CH1 Red |l C10 0 O CH OCHgCHIOCIhC H1011 CHI Y O OH ClCOOC H. Rad:

10 I? NH:

@wyocmcmoa I l n O H Shade 011 polyethylene glycol terephthalata Number Anthraqulnone compound Halogen formic acid ester fibres ll Same as number 10 CICOOCH Red.-

do ClC0OC|H1 Red. CICOOC'H" Bed.

Red. CIC 0 O H CICOOCILCHflir Red.

H ClCOOCH; CH; Red. A OCHaCHzO-Q-OCHzCHnOH 17 h) IIJH: CICOOCH: Blue.

S CH:CH:OH

S -CH1CH2O H Y I O NH} 18 (6 11111; ClCOOC|H Ruby red.

O scmcmcmoa \if I 19 0 NH, Red.

l l C1000 20. 88111685 8b0 8 -:.':r.'. CICOOCgH Red.

21. 0 NH; Red:

I l CICOO- 22 Sameasabove CICOOC1H| Red.

23 0 NH; ClCOOCzHl Bed:

OCH CH OCH CH OH 4 Same as above Red.

25 O NH; Barns as above... Red.

I (OCHgCHs)$OH 26 Same as above CICOOCJI Red.

27 fl) IT'H, ClCOOC1H| Red.-

| ocmcn,)on

l l i TABLE 1-Continued Shade on poly ethyleneglyeolterephthalate Number Anthraqulnone compound Halogen formic acid ester fibres 28 Same as number 27 Bed.

Cl C 0 29 (I? IFH, CICOOCIHI Red.

0 CHzCHzCHOH 30 (I? NH, 010000 11. Ruby red.

S CHiCHIOCHjCHlOH 30s 0 NH; Red.

ll l Cl-C 0-0 o oH.cHr-0-omom-orr H ll AH 30b Same as above... CH. Red.

Cl-C 0-0 EXAMPLE 31 '40.6 g. of 1,5-dihydroxy 4,8 diamino 2 (4'-fl-hy droxyethoxy) phenylanthraquiuone are homogeneously mixed by stirring in 400 g. of N,N-dimethylaniline and to the mixture are added at 540, 16..3 g. of chloroformic acid ethyl ester within half an hour. After a further hour at this temperature, the reaction mixture is diluted with 200 g. of ethanol, whereupon the dyestufi of the formula OH OCHiCHOCOOCIHI $11 ll I'm.

precipitates in a line form. It is filtered off, washed with ethanol and dried.

Polyethylene glycol terephthalate fibres are dyed, in the aqueous dispersion of the finely divided dyestuif, in clear blue shades. The dyeings have very good fastness to light and to sublimation.

By using in the above example, instead of the 16.3 g. of chloroformic acid ethyl ester, 27 g. of the same substance, or by performing the reaction at 25-30, a dyestuff is obtained which produces somewhat more reddish blue shades on polyethylene glycol terephthalate fibres.

EXAMPLE 32 7 g. of potassium carbonate and 34.5 g. of l-amino4- hydoxy 2 B;y-dihydroxypropylmercaptoanthraquinone are homogeneously mixed by stirring in 380 g. of chlorobenzene and to the mixture are added, at 0-l0 and in the course of 45 minutes, 24.5 g. of chloroformic acid I CH:

5 CH:CH-CH:OC 000% lies precipitates as black-violet powder. It is filtered ofl", washed with petroleum ether and with water and dried.

The aqueous dispersion of the finely divided dyestufi dyes cellulose diand triacetate fibres as well as, in particular, polyethylene glycol terephthalate fibres, in full, even, blueish-red shades. The dyeiugs have good fastness to light, rubbing and wet processing.

The same dyestulf is obtained by using in the above example, instead of the 24.5 g. of chloroformic acid isopropyl ester, 33.4 g. of bromoformic acid isopropyl ester, using otherwise the same procedure as prescribed above.

If, instead of the 34.5 g. of l-amino-4-hydroxy-2-p;ydihydroxypropylmercaptoanthraquinone, e q u iv ale n t amounts of an anthraquinone compounud listed in the following Table 2, column II, are used, and instead of the 24.5 g. of chloroformic acid isopropyl ester, equivalent amounts of a halogen formic acid ester given in column III of the same table, using otherwise the same procedure as described in the example, then dyestuffs are obtained which dye polyethylene glycol terephthalate fibres in the shades listed in column IV of this table, these shades likewise having fastness: to light and to sublimation.

TABLE 2 Shade on polyethylene glycol terephthalate Number Anthrequlnone compound Halogen formic acid ester fibres 33 NH; CH. Blnlsh red.

(31C O C B -CH,CH -O H O OH 34 Same as above Do.

35 do- CICOOCH. Do. as do C100 0 CHgCH. Do. 37 ClCOOChH, Do.

38 do. D0.

39...: .5 IO XIIH; C 0 O CsH D0.

SCH|CHCH|OH 40 Same as above Do.

EXAMPLE 4 1 dihydroisoindole, proceeding otherwise according to the To a mixture of 350 g. of chlorobenzene and 80 g. of triethylamine are added 35.1 g. of 1,4-diaminoanthraquinone-2,3 l-dicar-boxylic acid -p-hydroxyethylimide and homogeneously mixed by stirring at 40. The suspension is cooled to 0-10 and 19 g. of chloroformic-acid methyl ester are added dropwise in the course of half an hour. To complete the reaction, stirring is carried out for a further hour at this temperature. 200 g. of methanol are then added, whereupon the corresponding dyestufi of the formula H N-cmcrdo c doom 1 c NH'A precipitates in' a finely divided form from the reaction mixture. The dyestufi is filtered ofi, washed with methanol and dried.

' Fabrics made from polyethylene glycol'terephthalate fibres are dyed from the aqueous dispersion of the finely divided dyestuff in very pure, even, turquoise bluesha'des. The dyeings have good fastness to light and to rubbing. If, in the above example, instead of 19 g. of chloroformic acid methylester, 26.3 g. of chloroformic acid'nbutylester or 21.7 g. of chloroformic acid ethylester are used, then two further dyestuffs are obtained which produce turquoise blue dyeings on polyethylene glycol terephthalatefibres. A very similar dyestuli is also obtained by using instead of the 35.1 g. of 1,4-diaminoanthraquinone- 2,3 dicarboxylic acid ,8 hydroxyethylimide, 36.5 g. of 2,3-dicarboxylic acid-vhydroxypropylimide, and otherwise acylating as in the above example. A somewhat less greenishblue dyestuti is obtained by replacing, in the above example, the 35.1 g. of l,4-diamino-anthraquinone-2,3- dicarboxylic acid-,B-hydroxyethylimide by 35 g. of lamino-2-p-hydroxyethyl-3-oxo-4,7-diamino-5,6-phthaloyl above example.

EXAMPLE 42 34.4 g. of 1-amino-Z-hydroxymethyl-4-phenylaminoanthraquinone are dissolved, whilst heat is being applied,

in 300 g. of pyridine. The deep blue solution is cooled to hours "at 0-10 to "complete the l-5 and to this are added dropwise at this temperature, whilst the solution is being well stirred, 28 g. of chloroformic acid amyl ester; After the dropwise addition is completed, the reaction mixture is stirred for afurther 3 acylation. To etIect precipitation of the dyestufi of the formula O NH:

cmocoo-n-oln 200 g. of methanol are then added to the reaction mixture. The dyestutf is separated by filtration, washed with methanol and dried.

The finely divided dyestutf evenly dyes fibres made from cellulose diand triacetate, as well aspolyethylene' glycol terephthalate fibres, in aqueous dispersion, in deep blue shades having good fastness to light and to sublimation.

By using, instead of the 34.4 g. of 1-amino-2-hydroxyniethyl-4-phenylaminoanthraquinone, equivalent amounts TABLE 3 Shade on polyethylene yco Numterephthalate be: Anthraquinone compound Halogen formic acid ester fibres 43 O N H; Bad.

I I C10 0 0 CH:

C H: O H

44-...--.: (I) NH /CH; Reddish blue.

01C 0 0 C H C HzOH CHIC! 45 3 NH, clcoocmcmcmcl Red.

" CHIOH 4o f) IIIH: clcoocmcmnr ma.

mOQCEOH 41 0 NH: BrCOOCzH; Blue:

CHaQH NH-Q-OCH:

4s 0 OH Violet;

l i c1000 CHzOH 49 Same as above Cl-OOO-n-(hHn Do.

50 NH: CICOOCHI B1116;

HzOH

51 581116 58 above (ll-COOCzHl D0. 52 do ClCOOC(Ha(n) D0.

53 do Do.

54.--...': O NH: C1-COO-CH Red-violet.

\ JUS wW EXAMPLE 5s 39 g. of 1-amino-2-fl-hydroxyethylmercapto-4-anilinoanthraquinone are roughly dissolved at 20-25 in 400 g. of pyridine and to this solution are added dropwise, during 15 minutes at 5-l0, 16.3 g. of chloroformic acid ethyl ester. The acylation is completed after a further half an hour at this temperature. The dyestuff of the formula CH|CH|O C 0 002116 20 precipitates, upon the addition of 400 g. of methanol, in crystalline form; the dyestulf is filtered off, washed with methanol and dried.

The finely divided dyestuff very evenly dyes, in aqueous dispersion, fabrics made from polyethylene glycol terephthalate fibres in deep blue shades having very good fastness to rubbing and to sublimation.

By using, instead of 39 g. of 1-amino-2-f3-hydroxyethylmereapto-4-anilinoanthraquinone, equivalent amounts of an anthraquinone compound given in the following Table 4, column II, and instead of 16.3 g. of chloroformic acid ethyl ester, halogen formic acid ester, using otherwise the same procedure as described in the example, dyestuffsare obtained which dye polyethylene glycol terephthalate fibres in the shades listed 1n column IV of this table.

TABLE 4 Shade on pol ethylene glycol teraphthalate Number Anthraquinone compound Halogen formic acid ester fibres 56 O NH, CICOOCHzCHCh Blue.

S CHICHlOH CH: Y NH OH;

57.222.22.22 0 NH: C10 0 O 02H; D0;

OH S CHaJJHCHzOH l NH 58,..222222 '0 NH: Cl-GOOCzHqCl Violet;

O CHaCHzOH CH1 HQ. H1

59....222222 NH: ClCOOCHn Violet-blue;

O CHzC H1011 80-..222222 0 NH Blu I s 0H 0 s omcnomon cacao-Q CH; NHC

61.212222: 0 NH: C1-COOC:H; D0:

S-CHzCHzOH EXAMPLE 71 (i) NH;

o-Q-somnomomocooonzm:

lie

24 gradually precipitates in a finecrystalline form. The reaction product is filtered ofi, washed on the filter with ethyl alcohol and afterwards dried.

The finely divided dyestuff dyes polyethylene glycol terephthalate fibres, in aqueous dispersion, in brilliant red shades having very good fastness to light, sublimation and rubbing.

By using, instead of the 45.4 g. of 1-amino-4-hydroxyanthraquinone-Z-phenoxy-4-sulphonic acid )3 hydroxyethylamide, equivalent amounts of an anthraquinone compound given in the following Table 5, column 11, and instead of the 33 g. of chloroformic acid-fi-bromoethyl ester, equivalent amounts of a halogen formic acid ester, given in column III of the same table, with otherwise the same procedure as described in the example, dyestufis are obtained which dye polyethylene glycol terephthalate fibres in the shades listed in column IV of this table, these shades likewise having fastness to light and sublimation.

TABLE 5 Shade on polyethylene glycol terephthelate Number Anthraqulnone compound Halogen formic acid ester fibres 72-..;.;;---.'-; O NH: CICOO CH; Red violet War-1am O NH; (II-COOCsHtBl D0:

--eotmlomomon o-Q-wmnomormn a 74...:m IiI 01-0 0 0 0301] D0:

oQomnomomomon 75 O NH: CICOOCIH Ruby red;

s-Qs omrtcmorromon 76 ('3 NH: C1COOC|H1 D0:

s-Q-eomn-om-cmomon 17 0 NH CICOOCQH Red:

O-Q-eOmHQmomOH 78...:tzm: O NH; Bed."

CIC 0 O o-Q-eoamcmomon TABLE Continued Shade on polyethylene glycol terephthalate Number .Anthruqulnone compound Halogentormic acid ester fibres 79..-. .11- Same as number 78 C1COOC4H| Orange.

80. O NH; 010000 11; Ruby red;

wSQS omnomomon EXAMPLE 81 39.1 g. of l-amino-4-hydroxy-2-(4'-fl-hydroxyethoxyphenoxy)-anthraquinone are sprinkled into 350 ml. of pyridine at 35-40 Whilst the mixture is being vigorously dine are added in small portions at 010, whilst the solution is being vigorously stirred, 46.6 g. of chloroformic acid-p-methylphenyl ester within one hour. To complete the reaction, the reaction mixture is held at this o l0 temperature for a further two hours. By the slow dropstirred. The mixture is cooled to -15 and to it are added, in small portions, 43.3 g. of chloroformic acid g jg fi of 50 of Water the dyestufi of the tribromoethyl ester. Stirring is maintained at this tema perature until the starting material can no longer be detected by thin-layer chromatography. 0

With the addition of 350 ml. of methanol, the formed l dyestuff of the formula oonnomomomocooQ-cm o-Q-oomcmocoocmcm A H is precipitated as fine red powder. The dyestuff is filtered h tr d precipitates m the form of fine dark-red crystals from gg t gi g zggf 252 on 3 mm 31 an the reaction mixture. The dyestuif 1s filtered 01f, washed From aqueous dispersion, the finely divided dycstufi wlth methanol i water and dned' dyes fibres made from cellulose diand triacetate, as The finely dlvlded dyestufi .dyes P well as, in particular, fibres made from polyethylene thalate fibres, from aqueous dispersion, [11 even blueishterephthalate in very even red Shades having good fast red shades havlng excellent fastness to light, sublimation ness to light and to rubbing P By using, instead of the 31.2 g. of l-aminoanthra- If, m the above example, instead of 39.1 g. of l-ammoquinne 2 carbxyfic acidgrhydmxypmpylamide equiv 4 hydroxy 2 (4 -p-hydroxyethoxy-phcnoxy)-anfl aalent amounts of an anthraquinone compound given in qumonc of f the following Table 6, column 11, and instead of the ethoxy-phenylth1o)-anthraquinone and the same procedure 465 of hl f i acid p methoxyphenyl ester, as descl'lbed f' are used, than a lltqe more E equivalent amounts of a halogen formic acid ester given Ted f y havmg the same g dyeing p 18 in column 111 of the same table, with otherwise the same Obtamedprocedure as given in the example, dyestuffs are obtained EXAMPLE 82 which dye polyethylene glycol terephthalate fibres in the To a solution of 31.2 g. of l-aminoanthraquinone-Z- a s list in um V f this table, t e s d s carboxylic acid-'y-hydroxypropylamide in 300 mL of pyrilikewise having fastness to light and to sublimation.

TABLE 0 Shade on polyethylene glycol terephthalate Number Anthraqulnone compound Halogen formic acid ester fibres R d. 83 i I 01000 e CONHCHJJHICIEBOH m 84---::::::.:-: O N H CH6 B11161 CONHCHiCHIOH CH.

TABLE GContinued Shade on polyethylene glycol h l t 1 t Number Anthraquinone compound Halogen formic acid ester figf s a a e 94 (6 111B, CICOOCAH! Red.

@ so,0 cmornon 95 (I) 13TH, CICOOC=H| Blue.-

000011101110 CH CH OH 96 1TH; CICOOC4H| D0.

COOCHgCHzOH EXAMPLE 97 35 phonyl-4-phenylaminoanthraquinone, proceeding other- 423 g. of 1-hydroxy-2-,B-hydroxyethylsulphonyl-4-phenylaminoanthraquinone are homogeneously mixed by stirring at room temperature in 350 ml. of pyridine. After slight cooling of this mixture to -15", 34 g. of chloroformic acid butyl ester are added to it dropwise within minutes. The mixture is maintained at this temperature until the starting material is no longer detectable. The dyestuif of the formula SO CHgCHzOC 00 C411,

is precipitated, by the addition of 300 ml. of methanol, in a fine-crystalline form from the reaction mixture. The dyestutf is then filtered off, washed on the filter with methanol and dried.

With the finely divided dyestuff are obtained on polyethylene terephthalate fibres, from aqueous dispersion, even, deep, reddish blue shades having very good fastness to light and to sublimation.

A reddish blue dyestuff possessing similar properties is obtained by using, instead of 34 g. of chloroformic butyl ester, 19 g. of chloroforrnic acid methyl ester; a greenish blue dyestutf having similar good fastness properties is obtained by using, instead of the 42.3 g. of 1- hydroxy 2 5 hydroxyethylsulphonyl-4-phenylaminoanthraquinone, 42.2 g. of 1-amino-Z-fi-hydroxyethylsulwise according to the above example.

EXAMPLE 98 31.9 g. of 1,4-dihydroxy-2-bromoanthraquinone and 56 g. of 4'-(B-ethoxycarbonyloxy-ethoxy)-aniline are stirred up in 350 g. of boiling ethylene glycol monomethyl ether for 15 hours; to the deep violet-red reaction solution are added, at 100, 70 m1. of water and the solution is cooled to room temperature. The precipitated crystalline dyestufi of the formula o on @ONH-Q-O-CECHrO-COOQH;

ll 3m is then filtered off, washed with methanol and dried.

From an aqueous dispersion, the finely-divided dyestuff dyes fabric, made from polyethylene terephthalate fibres, in even red-violet shades having excellent fastness to light and to sublimation By using, instead of the 31.9 g. of 1,4-dihydroxy-2- bromoanthraquinone, equivalent amounts of an anthraquinone compound, given in the following Table 7, column II, and instead of the 56 g. of 4'-(/S-ethoxy-carbonyloxy-ethoxy)-aniline, equivalent amounts of an aniline derivative given in column II of the same table, with otherwise the same procedure as described in the example, dyestuffs are obtained which dye polyethylene glycol terephthalate fibres in the shades listed in column IV of this table, these shades likewise having fastness to light and to sublimation.

TABLE 7 Shade on plolyeltlzylene Anthraqulnone Halogen formic gli ala t Number compound aled ester fibres 9Q O O H Red.

M NH:-- 0011101110000 CH:

ll OH 100...'.-.';..--.': O OH Red.

l l NHr- CH:CH|OCOOC1H7 101 (I) ('I)H 011 Red.

B um-Q-oomcnomcooom.

?.-323-1: Same as above- -.-;.-...z:: Red.

NH OGH|CH:O-C0O Cl 103 do Red.

N -OCH|CH1OCO O 04H.

104 n n Nm-Qmcmcnmocoocm. ed

105 fin Red,

(EH10 C 0 0 04K.

1m I Red M rem-Q-Cmcmomocoocn.

EXAMPLE 107 30.4 g. of 1(N)-9-(2'-methyl)-pyridino-2-p-hydroxyethyl-aminoanthraquinone are homogeneously mixed in 300 g. of 3-picoline at 0-5; and at the same temperature are then added dropwise, within one hour, 31 g. of chloroformic acid phenyl ester. After 4 hours, the reaction product of the formula NHCmCm-O-OQOQ is precipitated from the mixture by the addition of 450 g. of methanol. It is filtered 01f, washed with methanol and dried.

From its finely divided aqueous dispersion, this dyestufi dyes polyethylene terephthalate fibres in intensely yellow shades having fastness to sublimation.

Very deeply colored, pure yellow dyestuifs, having very good fastness to sublimation, are obtained on polyethylene terephthalate fibres by replacing, in the above example, the 30.4 g. of l(N),9-(2'-methyl)-pyridino-2-;8-hydroxyethylaminoanthraquinone by 32.3 g. of 1(N),9 (N)-pyrimidino 2 B hydroxyethylthio-4-aminoanthraquinone and acylating by using either the same amount of chloroformic acid phenyl ester or by using 21.7 g. of chloroformic acid ethyl ester, under otherwise the same conditions.

EXAMPLE 108 To a solution of 800- g. of 96% sulphuric acid and 22 g. of o-boric acid are added, at 40-S0 and within /& hour, 48 g. of l,5-dihydroxy-4,8-diaminoauthraquinone- 3,6-disulphonic acid. The solution is cooled to 10 and to it are then added 38 g. of fi-monophenoxy-diethyl carbonate. Stirring is maintained for half an hour at 10 and the temperature than allowed to rise within half an hour to room temperature. After this period of time, the reaction mixture is poured on to two litres of ice/methanol (30% methanol) and then heated for 4 hours to 60.

The product of the formula NH: 3 OH HOaS is filtered 01f, washed with 5% brine and dried.

33 g. of the dried product are suspended in 400 ml. of 50% methanol, to the suspension are added 40 ml. of concentrated ammonia and to the whole are added drop- Wise 18 g. of sodium hyposulphite in 60 ml. water, the mixture being then heated for one hour to 4050.

temperature is completed after 2 hours. The reaction prodnot of the formula The dyestutf of the formula V I OH rim/ 1 ()H 6 OCHiCHIOCOOCIHI --oomorno 0000,11 Hos V 10 H IEIHQ 6 5 precipitates out in crystalline form as the solution is stirred with ice. The reaction product is filtered off, washed neuprecipitates out, is washed first with cold water, then with 3: water subsequently treated with mmhanol and hot water and finally with hot methanol, and dried. The dyesmfl. is identical to that obtaingd according to 31This dyestutf is identical to that stated under Example amPl" EXAMPLE 109 1r, instead of the 28.6 g. of 1,S-dihydroxy-4,8-diaminoanthraquinone equivalent amounts of the anthraquinone 28.6 g. of 1,S-dihydroxy-4,8-diaminoanthraquinone are compound given in the following Table 8, column H, are added to 270 ml. of 95% sulphuric acid at -30" within 20 used, or if the 30.5 g. of fi-monophenoxydiethyl carbonate minutes. The yellowish brown solution is cooled to are replaced with equivalent amounts of the phenoxy 0-5 and oxidized with 18 g. of manganese dioxide, withcompound given in column III of the same table, with in minutes, to the corresponding quinonimine. The otherwise the same procedure as described in the Examdeep-blue solution of the quinonimine is filtered through ple 109, then dyestuffs are obtained which dye polyetha glass frit, the residue washed with 180 ml. of 96% sul- 25 ylene glycol terephthalate fibres in shades having similar phuric acid, cooled to ---30 and 30.5 g. of B-mono-pheproperties, these shades being listed in column IV of the noxy-diethyl carbonate are added. The reaction at this same table.

TABLE 13 Shade on polyethylene terephthalate Number Anthraqulnone compound Halogen formic acid ester fibres NH: 0 0H Blue.

| H- -0CH|CH:OCO0CH:

HY XHg 111 Sameasabove CH; Do.

H-QOCHgCHg-O-COOC 112 d Do.

HOCH:CH:0CO0C4Hrn ll'i d0 D0.

H-Q-OCHaCHg-O-COOCaE-n 114 410.. CH| Do.

H@-OCHaCH,-0COOCHr-OE us A0" /CB' nocmonr-o-coo-cg 11a 1 Do.

H- -0CH1CHr-0COO Do. H-OCH1CH:O-CO0 H 112 Do. H-QOCHaCHz-O-COO-Q-Cl Do. do n--ocmom-o-coodo D0;

TABLE 8Contlnued Shade on polyethylene terephthalate Number Anthraqutnone compound Halogen formic acid ester fibres 121 Same as number 110 Blue.

H -O-CHCHCHOCOOC:H5

122 .do Do.

H -QCHzCH:-OCH:CHCOOCzHl 123 .do Dc.

H OCHzCHzCHlOCH1CH7CH3OCOOC2H5 HQ-OCHICHJOCHJCHaCH10-COOCzHs Do.

125 ..do Do.

H -0CHzCH1CII10CH1CHzOCOOCzHs 126.- do Q Do.

H OCHzCHgOCOOCHgCHzBI H H O OH Do. 127 0 i H HOCH,CH10CO0CzH;

l H N H-C H:

128 CIHBIFIH 11 Same as above- Do.

1 l H NH-CzH;

EXAMPLE 129 100 g. of fabric made from polyethylene glycol tereph- 28.6 g. of 1,5-dihydroxy-4,8-diaminoanthraquinone are introduced in small portions within half an hour at into 270 ml. of 96% sulphuric acid, whereupon the yellowish-brown solution is cooled to 0 and, within a further half hour, oxidized with 18 g. of manganese dioxide to quinonimine. The obtained deep blue solution is clarified through a glass frit and to the solution are added, at l0 to 5, 31 g. of ,B-(p-methylphenoxy) -ethylmethyl carbonate. .At this temperature the reaction is completed after one hour, the formed reaction product of the formula NH: OH CH:

H l H O NH:

EXAMPLE 130 In a pressure dyeing apparatus, 2 g. of the dyestuff, obtained according to Example 31, are finely suspended in 200 g. of water containing 4 g. of oleylpolyglycol ether. The pH value of the dye bath is adjusted with acetic acid to 4-5.

thalate are then introduced at 50, the dye bath is heated within 30 minutes to 140 and dyeing is carried out at this temperature for 50 minutes. The dyeing is afterwards rinsed with water, soaped and dried. Under these conditions is obtained a deeply colored, level, blue dyeing having fastness to perspiration, light and sublimation.

The dyestuff described in the other examples produce, using this process, dyeings of equal quality.

EXAMPLE 13 l Polyethylene glycol terephthalate fabric is impregnated on a padding machine at 40 with a dye liquor of the following composition:

20 g. of the dyestuff, obtained according to Example 32,

finely dispersed in 7.5 g. of sodium alginate,

20 g. of triethanolamine,

20 g. of octylphenolpolyglycol ether, and

900 g. of water.

The fabric, squeezed out to ca. is dried at 100 and afterwards fixed during 30 seconds at a temperature of 210. The dyed material is rinsed with water, soaped and dried. Under these conditions is obtained a deeply colored blueish-red dyeing having fastness to rubbing, light and sublimiation.

The dyestuffs described in the other examples produce, with application of this process, dyeings of equal quality.

EXAMPLE 132 A mixture consisting of 1 g. of the dyestutf obtained according to Example 1 and l g. of the dyestuff, obtained according to Example 10, are dispersed in 4000 g. of water. To this dispersion are added, as swelling agent, 12 g. of the sodium salt o-phenylphenol, as well as 12 g. of diammonium phosphate, and 100 g. of yarn made from polyethylene glycol terephthalate are dyed for 1 hours at 37 38 95-98". The dyeing is rinsed and afterwards treated with chlorine and lower alkoxy or by one to three lower aqueous sodium hydroxide solution and a dispersing agent. alkyl substituents,

In this manner is obtained a deeply coloured red dyeing X represents oxygen, sulphur, CONH, --SO NH- having fastness to light and to sublimation. or -O--alkylene-'O wherein the alkylene moiety By replacing, in the above example, the 100 g. of polyhas at most 4 carbon atoms, ethylene glycol terephthalate yarn by 100 g. of cellulose Y represents lower alkylene, and triacetate fabric, dyeing under the given conditions and R" represents lower alkyl, phenyl or phenyl substituted subsequently rinsing with water, a deeply colored red by one or two substituents selected from chlorine and dyeing is obtained having very good fastness to washing lower alkyl. and to sublim tion. 1O 3. An anthraquinone dyestuff as defined in claim 2 and What is claimed is: having the formula 1. An anthraquinone dyestufi of the formula O V! II O-CHzCH'z-O-COOCHL x-Y-o-o0 OR i) f, 4. An anthraquinone dyestuif as defined in claim 2 and wherein having the formula V represents hydroxyl or --NH 0 NH; V represents hydrogen, hydroxyl, cyclohexylamino,

phenylamino, or phenylamino ring substituted by one O-CHgCHr0-C 0 0-@ substituent selected from chlorine, C -C alkoxy or by one to three C C alkyl, represents oxygen, sullur, -C O O-- 0 ON H, (Oa1kylene)1-| 3 5 -O-, -Oethylene- S S -alkylene-O-, --Omethylene 5. An anthraqurnone dyestuff as defined in claim 2 and 3 having the formula phenylene,-Omethylene O ,-Ophenylene--, 0 NH:

wherein alkylene has up to 4 carbon atoms, represents alkylene of up to 4 carbon atoms or hydroxy- 0 0H alkylene of up to 4 carbon atoms, and 6. An anthraquinone dyestufi as defined in claim 2 and R represents alkyl of up to 5 carbon atoms, chlorohaving the formula alkyl of up to 5 carbon atoms, bromoalkyl of up to 0 5 carbon atoms, cyclohexyl, methylcyclohexyl, l phenyl, phenyl substituted by chlorine or lower alkyl, Q or alkenyl of up to 5 carbon atoms. 2. An anthraquinone dyestuff as defined in claim 1 and corresponding to the formula 8 I References Cited FOREIGN PATENTS 2,015,587 10/1970 Germany 260-376 Y i LORRAINE A. WEINBERGER, Primary Examiner wherein E. I. SKELLY, Assistant Examiner V represents hydroxyl or NH;, V represents hydroxyl, phenylamino or phenylamino ring-substituted by one substituent selected from 260-40 R, 347.2, 347.4, 372, 375, 376, 377 

